90

I've generally implemented sequence number generation using database sequences in the past.

e.g. Using Postgres SERIAL type http://www.neilconway.org/docs/sequences/

I'm curious though as how to generate sequence numbers for large distributed systems where there is no database. Does anybody have any experience or suggestions of a best practice for achieving sequence number generation in a thread safe manner for multiple clients?

13 Answers 13

109

OK, this is a very old question, which I'm first seeing now.

You'll need to differentiate between sequence numbers and unique IDs that are (optionally) loosely sortable by a specific criteria (typically generation time). True sequence numbers imply knowledge of what all other workers have done, and as such require shared state. There is no easy way of doing this in a distributed, high-scale manner. You could look into things like network broadcasts, windowed ranges for each worker, and distributed hash tables for unique worker IDs, but it's a lot of work.

Unique IDs are another matter, there are several good ways of generating unique IDs in a decentralized manner:

a) You could use Twitter's Snowflake ID network service. Snowflake is a:

  • Networked service, i.e. you make a network call to get a unique ID;
  • which produces 64 bit unique IDs that are ordered by generation time;
  • and the service is highly scalable and (potentially) highly available; each instance can generate many thousand IDs per second, and you can run multiple instances on your LAN/WAN;
  • written in Scala, runs on the JVM.

b) You could generate the unique IDs on the clients themselves, using an approach derived from how UUIDs and Snowflake's IDs are made. There are multiple options, but something along the lines of:

  • The most significant 40 or so bits: A timestamp; the generation time of the ID. (We're using the most significant bits for the timestamp to make IDs sort-able by generation time.)

  • The next 14 or so bits: A per-generator counter, which each generator increments by one for each new ID generated. This ensures that IDs generated at the same moment (same timestamps) do not overlap.

  • The last 10 or so bits: A unique value for each generator. Using this, we don't need to do any synchronization between generators (which is extremely hard), as all generators produce non-overlapping IDs because of this value.

c) You could generate the IDs on the clients, using just a timestamp and random value. This avoids the need to know all generators, and assign each generator a unique value. On the flip side, such IDs are not guaranteed to be globally unique, they're only very highly likely to be unique. (To collide, one or more generators would have to create the same random value at the exact same time.) Something along the lines of:

  • The most significant 32 bits: Timestamp, the generation time of the ID.
  • The least significant 32 bits: 32-bits of randomness, generated anew for each ID.

d) The easy way out, use UUIDs / GUIDs.

  • Cassandra supports counters (cassandra.apache.org/doc/cql3/CQL.html#counters), there are some limitations though. – Piyush Kansal Jan 17 '15 at 0:30
  • sequence numbers is easy to set position for bitmap index, but unique id sometimes too long (64bit or 128bit), how can unique id mapping to a bitmap index position? Thanks. – brucenan Nov 13 '15 at 6:30
  • 2
    really liked option #b ..... it could allow for high scale and not cause much of concurrency issue – puneet Jul 22 '16 at 6:40
  • 1
    twitter/snowflake is no longer maintained – Navin Aug 9 '18 at 0:09
  • If you want an Apache2 Licensed implementation of option B, check out bitbucket.org/pythagorasio/common-libraries/src/master/… You can also get it from maven io.pythagoras.common:distributed-sequence-id-generator:1.0.0 – Wpigott yesterday
15

You could have each node have a unique ID (which you may have anyway) and then prepend that to the sequence number.

For example, node 1 generates sequence 001-00001 001-00002 001-00003 etc. and node 5 generates 005-00001 005-00002

Unique :-)

Alternately if you want some sort of a centralized system, you could consider having your sequence server give out in blocks. This reduces the overhead significantly. For example, instead of requesting a new ID from the central server for each ID that must be assigned, you request IDs in blocks of 10,000 from the central server and then only have to do another network request when you run out.

  • 1
    i like your point about the batch id generation, but it just limits any real time calculation possibility. – ishan Jul 10 '15 at 18:19
  • I have implemented a similar mechanism. In that, in addition to clients caching a block of sequences, I have added several server-hosts that cache the blocks of sequences. A (single) master generator is maintained in some highly available storage or a single-master host, accessible only the fleet of server-hosts. The server caching would also help us in more uptime inspite the single master goes down for a moment. – Janakiram Sep 11 '15 at 19:04
13

Now there are more options.

Thou this question is "old", I got here, so I think it might be useful to leave the options I know of (so far):

  • You could try Hazelcast. In it's 1.9 release it includes a Distributed implementation of java.util.concurrent.AtomicLong
  • You can also use Zookeeper. It provides methods for creating sequence nodes (appended to znode names, thou I prefer using version numbers of the nodes). Be careful with this one thou: if you don't want missed numbers in your sequence, it may not be what you want.

Cheers

  • 3
    Zookeeper was the options I went with, there's a good description and writeup of this on the mailing list that I started - mail-archive.com/zookeeper-user@hadoop.apache.org/msg01967.html – Jon Oct 4 '10 at 19:17
  • Jon, thanks for pointing to that thread, that's exactly the type of solution I was thinking. BTW, did you make the code to overcome the MAX_INT limitation? – Paolo Oct 5 '10 at 19:16
11

It can be done with Redisson. It implements distributed and scalable version of AtomicLong. Here is example:

Config config = new Config();
config.addAddress("some.server.com:8291");

Redisson redisson = Redisson.create(config);
RAtomicLong atomicLong = redisson.getAtomicLong("anyAtomicLong");
atomicLong.incrementAndGet();
8

If it really has to be globally sequential, and not simply unique, then I would consider creating a single, simple service for dispensing these numbers.

Distributed systems rely on lots of little services interacting, and for this simple kind of task, do you really need or would you really benefit from some other complex, distributed solution?

  • 2
    ...and what happens when the server running that service goes down? – Navin Aug 9 '18 at 0:19
  • Have an alert that tells someone to start another one? Sometimes that will be just fine. I think the answer is trying to say "keep things in perspective". The perfect distributed solution has it's own drawbacks and sometimes simpler is better. – nic ferrier Jan 1 at 12:39
6

There are a few strategies; but none that i know can be really distributed and give a real sequence.

  1. have a central number generator. it doesn't have to be a big database. memcached has a fast atomic counter, in the vast majority of cases it's fast enough for your entire cluster.
  2. separate an integer range for each node (like Steven Schlanskter's answer)
  3. use random numbers or UUIDs
  4. use some piece of data, together with the node's ID, and hash it all (or hmac it)

personally, i'd lean to UUIDs, or memcached if i want to have a mostly-contiguous space.

4

Why not use a (thread safe) UUID generator?

I should probably expand on this.

UUIDs are guaranteed to be globally unique (if you avoid the ones based on random numbers, where the uniqueness is just highly probable).

Your "distributed" requirement is met, regardless of how many UUID generators you use, by the global uniqueness of each UUID.

Your "thread safe" requirement can be met by choosing "thread safe" UUID generators.

Your "sequence number" requirement is assumed to be met by the guaranteed global uniqueness of each UUID.

Note that many database sequence number implementations (e.g. Oracle) do not guarantee either monotonically increasing, or (even) increasing sequence numbers (on a per "connection" basis). This is because a consecutive batch of sequence numbers gets allocated in "cached" blocks on a per connection basis. This guarantees global uniqueness and maintains adequate speed. But the sequence numbers actually allocated (over time) can be jumbled when there are being allocated by multiple connections!

  • While UUIDs work, the problem with them is that you have to be careful how you store them if you ultimately need to index the generated keys. They will also typically take up a lot more space than a monotonically increased sequence. See percona.com/blog/2014/12/19/store-uuid-optimized-way for a discussion about storing them with MySQL. – Pavel Jun 20 '15 at 11:24
2

I know this is an old question but we were also facing the same need and was unable to find the solution that fulfills our need. Our requirement was to get a unique sequence (0,1,2,3...n) of ids and hence snowflake did not help. We created our own system to generate the ids using Redis. Redis is single threaded hence its list/queue mechanism would always give us 1 pop at a time.

What we do is, We create a buffer of ids, Initially, the queue will have 0 to 20 ids that are ready to be dispatched when requested. Multiple clients can request an id and redis will pop 1 id at a time, After every pop from left, we insert BUFFER + currentId to the right, Which keeps the buffer list going. Implementation here

1

Distributed ID generation can be archived with Redis and Lua. The implementation available in Github. It produces a distributed and k-sortable unique ids.

0

I have written a simple service which can generate semi-unique non-sequential 64 bit long numbers. It can be deployed on multiple machines for redundancy and scalability. It use ZeroMQ for messaging. For more information on how it works look at github page: zUID

0

Using a database you can reach 1.000+ increments per second with a single core. It is pretty easy. You can use its own database as backend to generate that number (as it should be its own aggregate, in DDD terms).

I had what seems a similar problem. I had several partitions and I wanted to get an offset counter for each one. I implemented something like this:

CREATE DATABASE example;
USE example;
CREATE TABLE offsets (partition INTEGER, offset LONG, PRIMARY KEY (partition));
INSERT offsets VALUES (1,0);

Then executed the following statement:

SELECT @offset := offset from offsets WHERE partition=1 FOR UPDATE;
UPDATE offsets set offset=@offset+1 WHERE partition=1;

If your application allows you, you can allocate a block at once (that was my case).

SELECT @offset := offset from offsets WHERE partition=1 FOR UPDATE;
UPDATE offsets set offset=@offset+100 WHERE partition=1;

If you need further throughput an cannot allocate offsets in advance you can implement your own service using Flink for real time processing. I was able to get around 100K increments per partition.

Hope it helps!

0

The problem is similar to: In iscsi world, where each luns/volumes have to be uniquely identifiable by the initiators running on the client side. The iscsi standard says that the first few bits have to represent the Storage provider/manufacturer information, and the rest monotonically increasing.

Similarly, one can use the initial bits in the distributed system of nodes to represent the nodeID and the rest can be monotonically increasing.

  • please add some more details – Ved Prakash Aug 23 '17 at 4:27
0

One solution that is decent is to use a long time based generation. It can be done with the backing of a distributed database.

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